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1 //===- lib/ReaderWriter/MachO/MachONormalizedFileFromAtoms.cpp ------------===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 
9 ///
10 /// \file Converts from in-memory Atoms to in-memory normalized mach-o.
11 ///
12 ///                  +------------+
13 ///                  | normalized |
14 ///                  +------------+
15 ///                        ^
16 ///                        |
17 ///                        |
18 ///                    +-------+
19 ///                    | Atoms |
20 ///                    +-------+
21 
22 #include "ArchHandler.h"
23 #include "DebugInfo.h"
24 #include "MachONormalizedFile.h"
25 #include "MachONormalizedFileBinaryUtils.h"
26 #include "lld/Common/LLVM.h"
27 #include "lld/Core/Error.h"
28 #include "llvm/ADT/StringRef.h"
29 #include "llvm/ADT/StringSwitch.h"
30 #include "llvm/BinaryFormat/MachO.h"
31 #include "llvm/Support/Casting.h"
32 #include "llvm/Support/Debug.h"
33 #include "llvm/Support/ErrorHandling.h"
34 #include "llvm/Support/Format.h"
35 #include <map>
36 #include <system_error>
37 #include <unordered_set>
38 
39 using llvm::StringRef;
40 using llvm::isa;
41 using namespace llvm::MachO;
42 using namespace lld::mach_o::normalized;
43 using namespace lld;
44 
45 namespace {
46 
47 struct AtomInfo {
48   const DefinedAtom  *atom;
49   uint64_t            offsetInSection;
50 };
51 
52 struct SectionInfo {
53   SectionInfo(StringRef seg, StringRef sect, SectionType type,
54               const MachOLinkingContext &ctxt, uint32_t attr,
55               bool relocsToDefinedCanBeImplicit);
56 
57   StringRef                 segmentName;
58   StringRef                 sectionName;
59   SectionType               type;
60   uint32_t                  attributes;
61   uint64_t                  address;
62   uint64_t                  size;
63   uint16_t                  alignment;
64 
65   /// If this is set, the any relocs in this section which point to defined
66   /// addresses can be implicitly generated.  This is the case for the
67   /// __eh_frame section where references to the function can be implicit if the
68   /// function is defined.
69   bool                      relocsToDefinedCanBeImplicit;
70 
71 
72   std::vector<AtomInfo>     atomsAndOffsets;
73   uint32_t                  normalizedSectionIndex;
74   uint32_t                  finalSectionIndex;
75 };
76 
SectionInfo(StringRef sg,StringRef sct,SectionType t,const MachOLinkingContext & ctxt,uint32_t attrs,bool relocsToDefinedCanBeImplicit)77 SectionInfo::SectionInfo(StringRef sg, StringRef sct, SectionType t,
78                          const MachOLinkingContext &ctxt, uint32_t attrs,
79                          bool relocsToDefinedCanBeImplicit)
80  : segmentName(sg), sectionName(sct), type(t), attributes(attrs),
81                  address(0), size(0), alignment(1),
82                  relocsToDefinedCanBeImplicit(relocsToDefinedCanBeImplicit),
83                  normalizedSectionIndex(0), finalSectionIndex(0) {
84   uint16_t align = 1;
85   if (ctxt.sectionAligned(segmentName, sectionName, align)) {
86     alignment = align;
87   }
88 }
89 
90 struct SegmentInfo {
91   SegmentInfo(StringRef name);
92 
93   StringRef                  name;
94   uint64_t                   address;
95   uint64_t                   size;
96   uint32_t                   init_access;
97   uint32_t                   max_access;
98   std::vector<SectionInfo*>  sections;
99   uint32_t                   normalizedSegmentIndex;
100 };
101 
SegmentInfo(StringRef n)102 SegmentInfo::SegmentInfo(StringRef n)
103  : name(n), address(0), size(0), init_access(0), max_access(0),
104    normalizedSegmentIndex(0) {
105 }
106 
107 class Util {
108 public:
Util(const MachOLinkingContext & ctxt)109   Util(const MachOLinkingContext &ctxt)
110       : _ctx(ctxt), _archHandler(ctxt.archHandler()), _entryAtom(nullptr),
111         _hasTLVDescriptors(false), _subsectionsViaSymbols(true) {}
112   ~Util();
113 
114   void      processDefinedAtoms(const lld::File &atomFile);
115   void      processAtomAttributes(const DefinedAtom *atom);
116   void      assignAtomToSection(const DefinedAtom *atom);
117   void      organizeSections();
118   void      assignAddressesToSections(const NormalizedFile &file);
119   uint32_t  fileFlags();
120   void      copySegmentInfo(NormalizedFile &file);
121   void      copySectionInfo(NormalizedFile &file);
122   void      updateSectionInfo(NormalizedFile &file);
123   void      buildAtomToAddressMap();
124   llvm::Error synthesizeDebugNotes(NormalizedFile &file);
125   llvm::Error addSymbols(const lld::File &atomFile, NormalizedFile &file);
126   void      addIndirectSymbols(const lld::File &atomFile, NormalizedFile &file);
127   void      addRebaseAndBindingInfo(const lld::File &, NormalizedFile &file);
128   void      addExportInfo(const lld::File &, NormalizedFile &file);
129   void      addSectionRelocs(const lld::File &, NormalizedFile &file);
130   void      addFunctionStarts(const lld::File &, NormalizedFile &file);
131   void      buildDataInCodeArray(const lld::File &, NormalizedFile &file);
132   void      addDependentDylibs(const lld::File &, NormalizedFile &file);
133   void      copyEntryPointAddress(NormalizedFile &file);
134   void      copySectionContent(NormalizedFile &file);
135 
allSourceFilesHaveMinVersions() const136   bool allSourceFilesHaveMinVersions() const {
137     return _allSourceFilesHaveMinVersions;
138   }
139 
minVersion() const140   uint32_t minVersion() const {
141     return _minVersion;
142   }
143 
minVersionCommandType() const144   LoadCommandType minVersionCommandType() const {
145     return _minVersionCommandType;
146   }
147 
148 private:
149   typedef std::map<DefinedAtom::ContentType, SectionInfo*> TypeToSection;
150   typedef llvm::DenseMap<const Atom*, uint64_t> AtomToAddress;
151 
152   struct DylibInfo { int ordinal; bool hasWeak; bool hasNonWeak; };
153   typedef llvm::StringMap<DylibInfo> DylibPathToInfo;
154 
155   SectionInfo *sectionForAtom(const DefinedAtom*);
156   SectionInfo *getRelocatableSection(DefinedAtom::ContentType type);
157   SectionInfo *getFinalSection(DefinedAtom::ContentType type);
158   void         appendAtom(SectionInfo *sect, const DefinedAtom *atom);
159   SegmentInfo *segmentForName(StringRef segName);
160   void         layoutSectionsInSegment(SegmentInfo *seg, uint64_t &addr);
161   void         layoutSectionsInTextSegment(size_t, SegmentInfo *, uint64_t &);
162   void         copySectionContent(SectionInfo *si, ContentBytes &content);
163   uint16_t     descBits(const DefinedAtom* atom);
164   int          dylibOrdinal(const SharedLibraryAtom *sa);
165   void         segIndexForSection(const SectionInfo *sect,
166                              uint8_t &segmentIndex, uint64_t &segmentStartAddr);
167   const Atom  *targetOfLazyPointer(const DefinedAtom *lpAtom);
168   const Atom  *targetOfStub(const DefinedAtom *stubAtom);
169   llvm::Error getSymbolTableRegion(const DefinedAtom* atom,
170                                    bool &inGlobalsRegion,
171                                    SymbolScope &symbolScope);
172   void         appendSection(SectionInfo *si, NormalizedFile &file);
173   uint32_t     sectionIndexForAtom(const Atom *atom);
174   void fixLazyReferenceImm(const DefinedAtom *atom, uint32_t offset,
175                            NormalizedFile &file);
176 
177   typedef llvm::DenseMap<const Atom*, uint32_t> AtomToIndex;
178   struct AtomAndIndex { const Atom *atom; uint32_t index; SymbolScope scope; };
179   struct AtomSorter {
180     bool operator()(const AtomAndIndex &left, const AtomAndIndex &right);
181   };
182   struct SegmentSorter {
183     bool operator()(const SegmentInfo *left, const SegmentInfo *right);
184     static unsigned weight(const SegmentInfo *);
185   };
186   struct TextSectionSorter {
187     bool operator()(const SectionInfo *left, const SectionInfo *right);
188     static unsigned weight(const SectionInfo *);
189   };
190 
191   const MachOLinkingContext &_ctx;
192   mach_o::ArchHandler          &_archHandler;
193   llvm::BumpPtrAllocator        _allocator;
194   std::vector<SectionInfo*>     _sectionInfos;
195   std::vector<SegmentInfo*>     _segmentInfos;
196   TypeToSection                 _sectionMap;
197   std::vector<SectionInfo*>     _customSections;
198   AtomToAddress                 _atomToAddress;
199   DylibPathToInfo               _dylibInfo;
200   const DefinedAtom            *_entryAtom;
201   AtomToIndex                   _atomToSymbolIndex;
202   std::vector<const Atom *>     _machHeaderAliasAtoms;
203   bool                          _hasTLVDescriptors;
204   bool                          _subsectionsViaSymbols;
205   bool                          _allSourceFilesHaveMinVersions = true;
206   LoadCommandType               _minVersionCommandType = (LoadCommandType)0;
207   uint32_t                      _minVersion = 0;
208   std::vector<lld::mach_o::Stab> _stabs;
209 };
210 
~Util()211 Util::~Util() {
212   // The SectionInfo structs are BumpPtr allocated, but atomsAndOffsets needs
213   // to be deleted.
214   for (SectionInfo *si : _sectionInfos) {
215     // clear() destroys vector elements, but does not deallocate.
216     // Instead use swap() to deallocate vector buffer.
217     std::vector<AtomInfo> empty;
218     si->atomsAndOffsets.swap(empty);
219   }
220   // The SegmentInfo structs are BumpPtr allocated, but sections needs
221   // to be deleted.
222   for (SegmentInfo *sgi : _segmentInfos) {
223     std::vector<SectionInfo*> empty2;
224     sgi->sections.swap(empty2);
225   }
226 }
227 
getRelocatableSection(DefinedAtom::ContentType type)228 SectionInfo *Util::getRelocatableSection(DefinedAtom::ContentType type) {
229   StringRef segmentName;
230   StringRef sectionName;
231   SectionType sectionType;
232   SectionAttr sectionAttrs;
233   bool relocsToDefinedCanBeImplicit;
234 
235   // Use same table used by when parsing .o files.
236   relocatableSectionInfoForContentType(type, segmentName, sectionName,
237                                        sectionType, sectionAttrs,
238                                        relocsToDefinedCanBeImplicit);
239   // If we already have a SectionInfo with this name, re-use it.
240   // This can happen if two ContentType map to the same mach-o section.
241   for (auto sect : _sectionMap) {
242     if (sect.second->sectionName.equals(sectionName) &&
243         sect.second->segmentName.equals(segmentName)) {
244       return sect.second;
245     }
246   }
247   // Otherwise allocate new SectionInfo object.
248   auto *sect = new (_allocator)
249       SectionInfo(segmentName, sectionName, sectionType, _ctx, sectionAttrs,
250                   relocsToDefinedCanBeImplicit);
251   _sectionInfos.push_back(sect);
252   _sectionMap[type] = sect;
253   return sect;
254 }
255 
256 #define ENTRY(seg, sect, type, atomType) \
257   {seg, sect, type, DefinedAtom::atomType }
258 
259 struct MachOFinalSectionFromAtomType {
260   StringRef                 segmentName;
261   StringRef                 sectionName;
262   SectionType               sectionType;
263   DefinedAtom::ContentType  atomType;
264 };
265 
266 const MachOFinalSectionFromAtomType sectsToAtomType[] = {
267   ENTRY("__TEXT", "__text",           S_REGULAR,          typeCode),
268   ENTRY("__TEXT", "__text",           S_REGULAR,          typeMachHeader),
269   ENTRY("__TEXT", "__cstring",        S_CSTRING_LITERALS, typeCString),
270   ENTRY("__TEXT", "__ustring",        S_REGULAR,          typeUTF16String),
271   ENTRY("__TEXT", "__const",          S_REGULAR,          typeConstant),
272   ENTRY("__TEXT", "__const",          S_4BYTE_LITERALS,   typeLiteral4),
273   ENTRY("__TEXT", "__const",          S_8BYTE_LITERALS,   typeLiteral8),
274   ENTRY("__TEXT", "__const",          S_16BYTE_LITERALS,  typeLiteral16),
275   ENTRY("__TEXT", "__stubs",          S_SYMBOL_STUBS,     typeStub),
276   ENTRY("__TEXT", "__stub_helper",    S_REGULAR,          typeStubHelper),
277   ENTRY("__TEXT", "__gcc_except_tab", S_REGULAR,          typeLSDA),
278   ENTRY("__TEXT", "__eh_frame",       S_COALESCED,        typeCFI),
279   ENTRY("__TEXT", "__unwind_info",    S_REGULAR,          typeProcessedUnwindInfo),
280   ENTRY("__DATA", "__data",           S_REGULAR,          typeData),
281   ENTRY("__DATA", "__const",          S_REGULAR,          typeConstData),
282   ENTRY("__DATA", "__cfstring",       S_REGULAR,          typeCFString),
283   ENTRY("__DATA", "__la_symbol_ptr",  S_LAZY_SYMBOL_POINTERS,
284                                                           typeLazyPointer),
285   ENTRY("__DATA", "__mod_init_func",  S_MOD_INIT_FUNC_POINTERS,
286                                                           typeInitializerPtr),
287   ENTRY("__DATA", "__mod_term_func",  S_MOD_TERM_FUNC_POINTERS,
288                                                           typeTerminatorPtr),
289   ENTRY("__DATA", "__got",            S_NON_LAZY_SYMBOL_POINTERS,
290                                                           typeGOT),
291   ENTRY("__DATA", "__nl_symbol_ptr",  S_NON_LAZY_SYMBOL_POINTERS,
292                                                           typeNonLazyPointer),
293   ENTRY("__DATA", "__thread_vars",    S_THREAD_LOCAL_VARIABLES,
294                                                           typeThunkTLV),
295   ENTRY("__DATA", "__thread_data",    S_THREAD_LOCAL_REGULAR,
296                                                           typeTLVInitialData),
297   ENTRY("__DATA", "__thread_ptrs",    S_THREAD_LOCAL_VARIABLE_POINTERS,
298                                                           typeTLVInitializerPtr),
299   ENTRY("__DATA", "__thread_bss",     S_THREAD_LOCAL_ZEROFILL,
300                                                          typeTLVInitialZeroFill),
301   ENTRY("__DATA", "__bss",            S_ZEROFILL,         typeZeroFill),
302   ENTRY("__DATA", "__interposing",    S_INTERPOSING,      typeInterposingTuples),
303 };
304 #undef ENTRY
305 
getFinalSection(DefinedAtom::ContentType atomType)306 SectionInfo *Util::getFinalSection(DefinedAtom::ContentType atomType) {
307   for (auto &p : sectsToAtomType) {
308     if (p.atomType != atomType)
309       continue;
310     SectionAttr sectionAttrs = 0;
311     switch (atomType) {
312     case DefinedAtom::typeMachHeader:
313     case DefinedAtom::typeCode:
314     case DefinedAtom::typeStub:
315     case DefinedAtom::typeStubHelper:
316       sectionAttrs = S_ATTR_PURE_INSTRUCTIONS | S_ATTR_SOME_INSTRUCTIONS;
317       break;
318     case DefinedAtom::typeThunkTLV:
319       _hasTLVDescriptors = true;
320       break;
321     default:
322       break;
323     }
324     // If we already have a SectionInfo with this name, re-use it.
325     // This can happen if two ContentType map to the same mach-o section.
326     for (auto sect : _sectionMap) {
327       if (sect.second->sectionName.equals(p.sectionName) &&
328           sect.second->segmentName.equals(p.segmentName)) {
329         return sect.second;
330       }
331     }
332     // Otherwise allocate new SectionInfo object.
333     auto *sect = new (_allocator) SectionInfo(
334         p.segmentName, p.sectionName, p.sectionType, _ctx, sectionAttrs,
335         /* relocsToDefinedCanBeImplicit */ false);
336     _sectionInfos.push_back(sect);
337     _sectionMap[atomType] = sect;
338     return sect;
339   }
340   llvm_unreachable("content type not yet supported");
341 }
342 
sectionForAtom(const DefinedAtom * atom)343 SectionInfo *Util::sectionForAtom(const DefinedAtom *atom) {
344   if (atom->sectionChoice() == DefinedAtom::sectionBasedOnContent) {
345     // Section for this atom is derived from content type.
346     DefinedAtom::ContentType type = atom->contentType();
347     auto pos = _sectionMap.find(type);
348     if ( pos != _sectionMap.end() )
349       return pos->second;
350     bool rMode = (_ctx.outputMachOType() == llvm::MachO::MH_OBJECT);
351     return rMode ? getRelocatableSection(type) : getFinalSection(type);
352   } else {
353     // This atom needs to be in a custom section.
354     StringRef customName = atom->customSectionName();
355     // Look to see if we have already allocated the needed custom section.
356     for(SectionInfo *sect : _customSections) {
357       const DefinedAtom *firstAtom = sect->atomsAndOffsets.front().atom;
358       if (firstAtom->customSectionName().equals(customName)) {
359         return sect;
360       }
361     }
362     // Not found, so need to create a new custom section.
363     size_t seperatorIndex = customName.find('/');
364     assert(seperatorIndex != StringRef::npos);
365     StringRef segName = customName.slice(0, seperatorIndex);
366     StringRef sectName = customName.drop_front(seperatorIndex + 1);
367     auto *sect =
368         new (_allocator) SectionInfo(segName, sectName, S_REGULAR, _ctx,
369                                      0, /* relocsToDefinedCanBeImplicit */ false);
370     _customSections.push_back(sect);
371     _sectionInfos.push_back(sect);
372     return sect;
373   }
374 }
375 
appendAtom(SectionInfo * sect,const DefinedAtom * atom)376 void Util::appendAtom(SectionInfo *sect, const DefinedAtom *atom) {
377   // Figure out offset for atom in this section given alignment constraints.
378   uint64_t offset = sect->size;
379   DefinedAtom::Alignment atomAlign = atom->alignment();
380   uint64_t align = atomAlign.value;
381   uint64_t requiredModulus = atomAlign.modulus;
382   uint64_t currentModulus = (offset % align);
383   if ( currentModulus != requiredModulus ) {
384     if ( requiredModulus > currentModulus )
385       offset += requiredModulus-currentModulus;
386     else
387       offset += align+requiredModulus-currentModulus;
388   }
389   // Record max alignment of any atom in this section.
390   if (align > sect->alignment)
391     sect->alignment = atomAlign.value;
392   // Assign atom to this section with this offset.
393   AtomInfo ai = {atom, offset};
394   sect->atomsAndOffsets.push_back(ai);
395   // Update section size to include this atom.
396   sect->size = offset + atom->size();
397 }
398 
processDefinedAtoms(const lld::File & atomFile)399 void Util::processDefinedAtoms(const lld::File &atomFile) {
400   for (const DefinedAtom *atom : atomFile.defined()) {
401     processAtomAttributes(atom);
402     assignAtomToSection(atom);
403   }
404 }
405 
processAtomAttributes(const DefinedAtom * atom)406 void Util::processAtomAttributes(const DefinedAtom *atom) {
407   if (auto *machoFile = dyn_cast<mach_o::MachOFile>(&atom->file())) {
408     // If the file doesn't use subsections via symbols, then make sure we don't
409     // add that flag to the final output file if we have a relocatable file.
410     if (!machoFile->subsectionsViaSymbols())
411       _subsectionsViaSymbols = false;
412 
413     // All the source files must have min versions for us to output an object
414     // file with a min version.
415     if (auto v = machoFile->minVersion())
416       _minVersion = std::max(_minVersion, v);
417     else
418       _allSourceFilesHaveMinVersions = false;
419 
420     // If we don't have a platform load command, but one of the source files
421     // does, then take the one from the file.
422     if (!_minVersionCommandType)
423       if (auto v = machoFile->minVersionLoadCommandKind())
424         _minVersionCommandType = v;
425   }
426 }
427 
assignAtomToSection(const DefinedAtom * atom)428 void Util::assignAtomToSection(const DefinedAtom *atom) {
429   if (atom->contentType() == DefinedAtom::typeMachHeader) {
430     _machHeaderAliasAtoms.push_back(atom);
431     // Assign atom to this section with this offset.
432     AtomInfo ai = {atom, 0};
433     sectionForAtom(atom)->atomsAndOffsets.push_back(ai);
434   } else if (atom->contentType() == DefinedAtom::typeDSOHandle)
435     _machHeaderAliasAtoms.push_back(atom);
436   else
437     appendAtom(sectionForAtom(atom), atom);
438 }
439 
segmentForName(StringRef segName)440 SegmentInfo *Util::segmentForName(StringRef segName) {
441   for (SegmentInfo *si : _segmentInfos) {
442     if ( si->name.equals(segName) )
443       return si;
444   }
445   auto *info = new (_allocator) SegmentInfo(segName);
446 
447   // Set the initial segment protection.
448   if (segName.equals("__TEXT"))
449     info->init_access = VM_PROT_READ | VM_PROT_EXECUTE;
450   else if (segName.equals("__PAGEZERO"))
451     info->init_access = 0;
452   else if (segName.equals("__LINKEDIT"))
453     info->init_access = VM_PROT_READ;
454   else {
455     // All others default to read-write
456     info->init_access = VM_PROT_READ | VM_PROT_WRITE;
457   }
458 
459   // Set max segment protection
460   // Note, its overkill to use a switch statement here, but makes it so much
461   // easier to use switch coverage to catch new cases.
462   switch (_ctx.os()) {
463     case lld::MachOLinkingContext::OS::unknown:
464     case lld::MachOLinkingContext::OS::macOSX:
465     case lld::MachOLinkingContext::OS::iOS_simulator:
466       if (segName.equals("__PAGEZERO")) {
467         info->max_access = 0;
468         break;
469       }
470       // All others default to all
471       info->max_access = VM_PROT_READ | VM_PROT_WRITE | VM_PROT_EXECUTE;
472       break;
473     case lld::MachOLinkingContext::OS::iOS:
474       // iPhoneOS always uses same protection for max and initial
475       info->max_access = info->init_access;
476       break;
477   }
478   _segmentInfos.push_back(info);
479   return info;
480 }
481 
weight(const SegmentInfo * seg)482 unsigned Util::SegmentSorter::weight(const SegmentInfo *seg) {
483  return llvm::StringSwitch<unsigned>(seg->name)
484     .Case("__PAGEZERO",  1)
485     .Case("__TEXT",      2)
486     .Case("__DATA",      3)
487     .Default(100);
488 }
489 
operator ()(const SegmentInfo * left,const SegmentInfo * right)490 bool Util::SegmentSorter::operator()(const SegmentInfo *left,
491                                   const SegmentInfo *right) {
492   return (weight(left) < weight(right));
493 }
494 
weight(const SectionInfo * sect)495 unsigned Util::TextSectionSorter::weight(const SectionInfo *sect) {
496  return llvm::StringSwitch<unsigned>(sect->sectionName)
497     .Case("__text",         1)
498     .Case("__stubs",        2)
499     .Case("__stub_helper",  3)
500     .Case("__const",        4)
501     .Case("__cstring",      5)
502     .Case("__unwind_info",  98)
503     .Case("__eh_frame",     99)
504     .Default(10);
505 }
506 
operator ()(const SectionInfo * left,const SectionInfo * right)507 bool Util::TextSectionSorter::operator()(const SectionInfo *left,
508                                          const SectionInfo *right) {
509   return (weight(left) < weight(right));
510 }
511 
organizeSections()512 void Util::organizeSections() {
513   // NOTE!: Keep this in sync with assignAddressesToSections.
514   switch (_ctx.outputMachOType()) {
515     case llvm::MachO::MH_EXECUTE:
516       // Main executables, need a zero-page segment
517       segmentForName("__PAGEZERO");
518       // Fall into next case.
519       LLVM_FALLTHROUGH;
520     case llvm::MachO::MH_DYLIB:
521     case llvm::MachO::MH_BUNDLE:
522       // All dynamic code needs TEXT segment to hold the load commands.
523       segmentForName("__TEXT");
524       break;
525     default:
526       break;
527   }
528   segmentForName("__LINKEDIT");
529 
530   // Group sections into segments.
531   for (SectionInfo *si : _sectionInfos) {
532     SegmentInfo *seg = segmentForName(si->segmentName);
533     seg->sections.push_back(si);
534   }
535   // Sort segments.
536   std::sort(_segmentInfos.begin(), _segmentInfos.end(), SegmentSorter());
537 
538   // Sort sections within segments.
539   for (SegmentInfo *seg : _segmentInfos) {
540     if (seg->name.equals("__TEXT")) {
541       std::sort(seg->sections.begin(), seg->sections.end(),
542                 TextSectionSorter());
543     }
544   }
545 
546   // Record final section indexes.
547   uint32_t segmentIndex = 0;
548   uint32_t sectionIndex = 1;
549   for (SegmentInfo *seg : _segmentInfos) {
550     seg->normalizedSegmentIndex = segmentIndex++;
551     for (SectionInfo *sect : seg->sections)
552       sect->finalSectionIndex = sectionIndex++;
553   }
554 }
555 
layoutSectionsInSegment(SegmentInfo * seg,uint64_t & addr)556 void Util::layoutSectionsInSegment(SegmentInfo *seg, uint64_t &addr) {
557   seg->address = addr;
558   for (SectionInfo *sect : seg->sections) {
559     sect->address = llvm::alignTo(addr, sect->alignment);
560     addr = sect->address + sect->size;
561   }
562   seg->size = llvm::alignTo(addr - seg->address, _ctx.pageSize());
563 }
564 
565 // __TEXT segment lays out backwards so padding is at front after load commands.
layoutSectionsInTextSegment(size_t hlcSize,SegmentInfo * seg,uint64_t & addr)566 void Util::layoutSectionsInTextSegment(size_t hlcSize, SegmentInfo *seg,
567                                                                uint64_t &addr) {
568   seg->address = addr;
569   // Walks sections starting at end to calculate padding for start.
570   int64_t taddr = 0;
571   for (auto it = seg->sections.rbegin(); it != seg->sections.rend(); ++it) {
572     SectionInfo *sect = *it;
573     taddr -= sect->size;
574     taddr = taddr & (0 - sect->alignment);
575   }
576   int64_t padding = taddr - hlcSize;
577   while (padding < 0)
578     padding += _ctx.pageSize();
579   // Start assigning section address starting at padded offset.
580   addr += (padding + hlcSize);
581   for (SectionInfo *sect : seg->sections) {
582     sect->address = llvm::alignTo(addr, sect->alignment);
583     addr = sect->address + sect->size;
584   }
585   seg->size = llvm::alignTo(addr - seg->address, _ctx.pageSize());
586 }
587 
assignAddressesToSections(const NormalizedFile & file)588 void Util::assignAddressesToSections(const NormalizedFile &file) {
589   // NOTE!: Keep this in sync with organizeSections.
590   size_t hlcSize = headerAndLoadCommandsSize(file,
591                                       _ctx.generateFunctionStartsLoadCommand());
592   uint64_t address = 0;
593   for (SegmentInfo *seg : _segmentInfos) {
594     if (seg->name.equals("__PAGEZERO")) {
595       seg->size = _ctx.pageZeroSize();
596       address += seg->size;
597     }
598     else if (seg->name.equals("__TEXT")) {
599       // _ctx.baseAddress()  == 0 implies it was either unspecified or
600       // pageZeroSize is also 0. In either case resetting address is safe.
601       address = _ctx.baseAddress() ? _ctx.baseAddress() : address;
602       layoutSectionsInTextSegment(hlcSize, seg, address);
603     } else
604       layoutSectionsInSegment(seg, address);
605 
606     address = llvm::alignTo(address, _ctx.pageSize());
607   }
608   DEBUG_WITH_TYPE("WriterMachO-norm",
609     llvm::dbgs() << "assignAddressesToSections()\n";
610     for (SegmentInfo *sgi : _segmentInfos) {
611       llvm::dbgs()  << "   address=" << llvm::format("0x%08llX", sgi->address)
612                     << ", size="  << llvm::format("0x%08llX", sgi->size)
613                     << ", segment-name='" << sgi->name
614                     << "'\n";
615       for (SectionInfo *si : sgi->sections) {
616         llvm::dbgs()<< "      addr="  << llvm::format("0x%08llX", si->address)
617                     << ", size="  << llvm::format("0x%08llX", si->size)
618                     << ", section-name='" << si->sectionName
619                     << "\n";
620       }
621     }
622   );
623 }
624 
copySegmentInfo(NormalizedFile & file)625 void Util::copySegmentInfo(NormalizedFile &file) {
626   for (SegmentInfo *sgi : _segmentInfos) {
627     Segment seg;
628     seg.name    = sgi->name;
629     seg.address = sgi->address;
630     seg.size    = sgi->size;
631     seg.init_access  = sgi->init_access;
632     seg.max_access  = sgi->max_access;
633     file.segments.push_back(seg);
634   }
635 }
636 
appendSection(SectionInfo * si,NormalizedFile & file)637 void Util::appendSection(SectionInfo *si, NormalizedFile &file) {
638    // Add new empty section to end of file.sections.
639   Section temp;
640   file.sections.push_back(std::move(temp));
641   Section* normSect = &file.sections.back();
642   // Copy fields to normalized section.
643   normSect->segmentName   = si->segmentName;
644   normSect->sectionName   = si->sectionName;
645   normSect->type          = si->type;
646   normSect->attributes    = si->attributes;
647   normSect->address       = si->address;
648   normSect->alignment     = si->alignment;
649   // Record where normalized section is.
650   si->normalizedSectionIndex = file.sections.size()-1;
651 }
652 
copySectionContent(NormalizedFile & file)653 void Util::copySectionContent(NormalizedFile &file) {
654   const bool r = (_ctx.outputMachOType() == llvm::MachO::MH_OBJECT);
655 
656   // Utility function for ArchHandler to find address of atom in output file.
657   auto addrForAtom = [&] (const Atom &atom) -> uint64_t {
658     auto pos = _atomToAddress.find(&atom);
659     assert(pos != _atomToAddress.end());
660     return pos->second;
661   };
662 
663   auto sectionAddrForAtom = [&] (const Atom &atom) -> uint64_t {
664     for (const SectionInfo *sectInfo : _sectionInfos)
665       for (const AtomInfo &atomInfo : sectInfo->atomsAndOffsets)
666         if (atomInfo.atom == &atom)
667           return sectInfo->address;
668     llvm_unreachable("atom not assigned to section");
669   };
670 
671   for (SectionInfo *si : _sectionInfos) {
672     Section *normSect = &file.sections[si->normalizedSectionIndex];
673     if (isZeroFillSection(si->type)) {
674       const uint8_t *empty = nullptr;
675       normSect->content = llvm::makeArrayRef(empty, si->size);
676       continue;
677     }
678     // Copy content from atoms to content buffer for section.
679     llvm::MutableArrayRef<uint8_t> sectionContent;
680     if (si->size) {
681       uint8_t *sectContent = file.ownedAllocations.Allocate<uint8_t>(si->size);
682       sectionContent = llvm::MutableArrayRef<uint8_t>(sectContent, si->size);
683       normSect->content = sectionContent;
684     }
685     for (AtomInfo &ai : si->atomsAndOffsets) {
686       if (!ai.atom->size()) {
687         assert(ai.atom->begin() == ai.atom->end() &&
688                "Cannot have references without content");
689         continue;
690       }
691       auto atomContent = sectionContent.slice(ai.offsetInSection,
692                                               ai.atom->size());
693       _archHandler.generateAtomContent(*ai.atom, r, addrForAtom,
694                                        sectionAddrForAtom, _ctx.baseAddress(),
695                                        atomContent);
696     }
697   }
698 }
699 
copySectionInfo(NormalizedFile & file)700 void Util::copySectionInfo(NormalizedFile &file) {
701   file.sections.reserve(_sectionInfos.size());
702   // Write sections grouped by segment.
703   for (SegmentInfo *sgi : _segmentInfos) {
704     for (SectionInfo *si : sgi->sections) {
705       appendSection(si, file);
706     }
707   }
708 }
709 
updateSectionInfo(NormalizedFile & file)710 void Util::updateSectionInfo(NormalizedFile &file) {
711   file.sections.reserve(_sectionInfos.size());
712   // sections grouped by segment.
713   for (SegmentInfo *sgi : _segmentInfos) {
714     Segment *normSeg = &file.segments[sgi->normalizedSegmentIndex];
715     normSeg->address = sgi->address;
716     normSeg->size = sgi->size;
717     for (SectionInfo *si : sgi->sections) {
718       Section *normSect = &file.sections[si->normalizedSectionIndex];
719       normSect->address = si->address;
720     }
721   }
722 }
723 
copyEntryPointAddress(NormalizedFile & nFile)724 void Util::copyEntryPointAddress(NormalizedFile &nFile) {
725   if (!_entryAtom) {
726     nFile.entryAddress = 0;
727     return;
728   }
729 
730   if (_ctx.outputTypeHasEntry()) {
731     if (_archHandler.isThumbFunction(*_entryAtom))
732       nFile.entryAddress = (_atomToAddress[_entryAtom] | 1);
733     else
734       nFile.entryAddress = _atomToAddress[_entryAtom];
735   }
736 }
737 
buildAtomToAddressMap()738 void Util::buildAtomToAddressMap() {
739   DEBUG_WITH_TYPE("WriterMachO-address", llvm::dbgs()
740                    << "assign atom addresses:\n");
741   const bool lookForEntry = _ctx.outputTypeHasEntry();
742   for (SectionInfo *sect : _sectionInfos) {
743     for (const AtomInfo &info : sect->atomsAndOffsets) {
744       _atomToAddress[info.atom] = sect->address + info.offsetInSection;
745       if (lookForEntry && (info.atom->contentType() == DefinedAtom::typeCode) &&
746           (info.atom->size() != 0) &&
747           info.atom->name() == _ctx.entrySymbolName()) {
748         _entryAtom = info.atom;
749       }
750       DEBUG_WITH_TYPE("WriterMachO-address", llvm::dbgs()
751                       << "   address="
752                       << llvm::format("0x%016X", _atomToAddress[info.atom])
753                       << llvm::format("    0x%09lX", info.atom)
754                       << ", file=#"
755                       << info.atom->file().ordinal()
756                       << ", atom=#"
757                       << info.atom->ordinal()
758                       << ", name="
759                       << info.atom->name()
760                       << ", type="
761                       << info.atom->contentType()
762                       << "\n");
763     }
764   }
765   DEBUG_WITH_TYPE("WriterMachO-address", llvm::dbgs()
766                   << "assign header alias atom addresses:\n");
767   for (const Atom *atom : _machHeaderAliasAtoms) {
768     _atomToAddress[atom] = _ctx.baseAddress();
769 #ifndef NDEBUG
770     if (auto *definedAtom = dyn_cast<DefinedAtom>(atom)) {
771       DEBUG_WITH_TYPE("WriterMachO-address", llvm::dbgs()
772                       << "   address="
773                       << llvm::format("0x%016X", _atomToAddress[atom])
774                       << llvm::format("    0x%09lX", atom)
775                       << ", file=#"
776                       << definedAtom->file().ordinal()
777                       << ", atom=#"
778                       << definedAtom->ordinal()
779                       << ", name="
780                       << definedAtom->name()
781                       << ", type="
782                       << definedAtom->contentType()
783                       << "\n");
784     } else {
785       DEBUG_WITH_TYPE("WriterMachO-address", llvm::dbgs()
786                       << "   address="
787                       << llvm::format("0x%016X", _atomToAddress[atom])
788                       << " atom=" << atom
789                       << " name=" << atom->name() << "\n");
790     }
791 #endif
792   }
793 }
794 
synthesizeDebugNotes(NormalizedFile & file)795 llvm::Error Util::synthesizeDebugNotes(NormalizedFile &file) {
796 
797   // Bail out early if we don't need to generate a debug map.
798   if (_ctx.debugInfoMode() == MachOLinkingContext::DebugInfoMode::noDebugMap)
799     return llvm::Error::success();
800 
801   std::vector<const DefinedAtom*> atomsNeedingDebugNotes;
802   std::set<const mach_o::MachOFile*> filesWithStabs;
803   bool objFileHasDwarf = false;
804   const File *objFile = nullptr;
805 
806   for (SectionInfo *sect : _sectionInfos) {
807     for (const AtomInfo &info : sect->atomsAndOffsets) {
808       if (const DefinedAtom *atom = dyn_cast<DefinedAtom>(info.atom)) {
809 
810         // FIXME: No stabs/debug-notes for symbols that wouldn't be in the
811         //        symbol table.
812         // FIXME: No stabs/debug-notes for kernel dtrace probes.
813 
814         if (atom->contentType() == DefinedAtom::typeCFI ||
815             atom->contentType() == DefinedAtom::typeCString)
816           continue;
817 
818         // Whenever we encounter a new file, update the 'objfileHasDwarf' flag.
819         if (&info.atom->file() != objFile) {
820           objFileHasDwarf = false;
821           if (const mach_o::MachOFile *atomFile =
822               dyn_cast<mach_o::MachOFile>(&info.atom->file())) {
823             if (atomFile->debugInfo()) {
824               if (isa<mach_o::DwarfDebugInfo>(atomFile->debugInfo()))
825                 objFileHasDwarf = true;
826               else if (isa<mach_o::StabsDebugInfo>(atomFile->debugInfo()))
827                 filesWithStabs.insert(atomFile);
828             }
829           }
830         }
831 
832         // If this atom is from a file that needs dwarf, add it to the list.
833         if (objFileHasDwarf)
834           atomsNeedingDebugNotes.push_back(info.atom);
835       }
836     }
837   }
838 
839   // Sort atoms needing debug notes by file ordinal, then atom ordinal.
840   std::sort(atomsNeedingDebugNotes.begin(), atomsNeedingDebugNotes.end(),
841             [](const DefinedAtom *lhs, const DefinedAtom *rhs) {
842               if (lhs->file().ordinal() != rhs->file().ordinal())
843                 return (lhs->file().ordinal() < rhs->file().ordinal());
844               return (lhs->ordinal() < rhs->ordinal());
845             });
846 
847   // FIXME: Handle <rdar://problem/17689030>: Add -add_ast_path option to \
848   //        linker which add N_AST stab entry to output
849   // See OutputFile::synthesizeDebugNotes in ObjectFile.cpp in ld64.
850 
851   StringRef oldFileName = "";
852   StringRef oldDirPath = "";
853   bool wroteStartSO = false;
854   std::unordered_set<std::string> seenFiles;
855   for (const DefinedAtom *atom : atomsNeedingDebugNotes) {
856     const auto &atomFile = cast<mach_o::MachOFile>(atom->file());
857     assert(dyn_cast_or_null<lld::mach_o::DwarfDebugInfo>(atomFile.debugInfo())
858            && "file for atom needing debug notes does not contain dwarf");
859     auto &dwarf = cast<lld::mach_o::DwarfDebugInfo>(*atomFile.debugInfo());
860 
861     auto &tu = dwarf.translationUnitSource();
862     StringRef newFileName = tu.name;
863     StringRef newDirPath = tu.path;
864 
865     // Add an SO whenever the TU source file changes.
866     if (newFileName != oldFileName || newDirPath != oldDirPath) {
867       // Translation unit change, emit ending SO
868       if (oldFileName != "")
869         _stabs.push_back(mach_o::Stab(nullptr, N_SO, 1, 0, 0, ""));
870 
871       oldFileName = newFileName;
872       oldDirPath = newDirPath;
873 
874       // If newDirPath doesn't end with a '/' we need to add one:
875       if (newDirPath.back() != '/') {
876         char *p =
877           file.ownedAllocations.Allocate<char>(newDirPath.size() + 2);
878         memcpy(p, newDirPath.data(), newDirPath.size());
879         p[newDirPath.size()] = '/';
880         p[newDirPath.size() + 1] = '\0';
881         newDirPath = p;
882       }
883 
884       // New translation unit, emit start SOs:
885       _stabs.push_back(mach_o::Stab(nullptr, N_SO, 0, 0, 0, newDirPath));
886       _stabs.push_back(mach_o::Stab(nullptr, N_SO, 0, 0, 0, newFileName));
887 
888       // Synthesize OSO for start of file.
889       char *fullPath = nullptr;
890       {
891         SmallString<1024> pathBuf(atomFile.path());
892         if (auto EC = llvm::sys::fs::make_absolute(pathBuf))
893           return llvm::errorCodeToError(EC);
894         fullPath = file.ownedAllocations.Allocate<char>(pathBuf.size() + 1);
895         memcpy(fullPath, pathBuf.c_str(), pathBuf.size() + 1);
896       }
897 
898       // Get mod time.
899       uint32_t modTime = 0;
900       llvm::sys::fs::file_status stat;
901       if (!llvm::sys::fs::status(fullPath, stat))
902         if (llvm::sys::fs::exists(stat))
903           modTime = llvm::sys::toTimeT(stat.getLastModificationTime());
904 
905       _stabs.push_back(mach_o::Stab(nullptr, N_OSO, _ctx.getCPUSubType(), 1,
906                                     modTime, fullPath));
907       // <rdar://problem/6337329> linker should put cpusubtype in n_sect field
908       // of nlist entry for N_OSO debug note entries.
909       wroteStartSO = true;
910     }
911 
912     if (atom->contentType() == DefinedAtom::typeCode) {
913       // Synthesize BNSYM and start FUN stabs.
914       _stabs.push_back(mach_o::Stab(atom, N_BNSYM, 1, 0, 0, ""));
915       _stabs.push_back(mach_o::Stab(atom, N_FUN, 1, 0, 0, atom->name()));
916       // Synthesize any SOL stabs needed
917       // FIXME: add SOL stabs.
918       _stabs.push_back(mach_o::Stab(nullptr, N_FUN, 0, 0,
919                                     atom->rawContent().size(), ""));
920       _stabs.push_back(mach_o::Stab(nullptr, N_ENSYM, 1, 0,
921                                     atom->rawContent().size(), ""));
922     } else {
923       if (atom->scope() == Atom::scopeTranslationUnit)
924         _stabs.push_back(mach_o::Stab(atom, N_STSYM, 1, 0, 0, atom->name()));
925       else
926         _stabs.push_back(mach_o::Stab(nullptr, N_GSYM, 1, 0, 0, atom->name()));
927     }
928   }
929 
930   // Emit ending SO if necessary.
931   if (wroteStartSO)
932     _stabs.push_back(mach_o::Stab(nullptr, N_SO, 1, 0, 0, ""));
933 
934   // Copy any stabs from .o file.
935   for (const auto *objFile : filesWithStabs) {
936     const auto &stabsList =
937       cast<mach_o::StabsDebugInfo>(objFile->debugInfo())->stabs();
938     for (auto &stab : stabsList) {
939       // FIXME: Drop stabs whose atoms have been dead-stripped.
940       _stabs.push_back(stab);
941     }
942   }
943 
944   return llvm::Error::success();
945 }
946 
descBits(const DefinedAtom * atom)947 uint16_t Util::descBits(const DefinedAtom* atom) {
948   uint16_t desc = 0;
949   switch (atom->merge()) {
950   case lld::DefinedAtom::mergeNo:
951   case lld::DefinedAtom::mergeAsTentative:
952     break;
953   case lld::DefinedAtom::mergeAsWeak:
954   case lld::DefinedAtom::mergeAsWeakAndAddressUsed:
955     desc |= N_WEAK_DEF;
956     break;
957   case lld::DefinedAtom::mergeSameNameAndSize:
958   case lld::DefinedAtom::mergeByLargestSection:
959   case lld::DefinedAtom::mergeByContent:
960     llvm_unreachable("Unsupported DefinedAtom::merge()");
961     break;
962   }
963   if (atom->contentType() == lld::DefinedAtom::typeResolver)
964     desc |= N_SYMBOL_RESOLVER;
965   if (atom->contentType() == lld::DefinedAtom::typeMachHeader)
966     desc |= REFERENCED_DYNAMICALLY;
967   if (_archHandler.isThumbFunction(*atom))
968     desc |= N_ARM_THUMB_DEF;
969   if (atom->deadStrip() == DefinedAtom::deadStripNever &&
970       _ctx.outputMachOType() == llvm::MachO::MH_OBJECT) {
971     if ((atom->contentType() != DefinedAtom::typeInitializerPtr)
972      && (atom->contentType() != DefinedAtom::typeTerminatorPtr))
973     desc |= N_NO_DEAD_STRIP;
974   }
975   return desc;
976 }
977 
operator ()(const AtomAndIndex & left,const AtomAndIndex & right)978 bool Util::AtomSorter::operator()(const AtomAndIndex &left,
979                                   const AtomAndIndex &right) {
980   return (left.atom->name().compare(right.atom->name()) < 0);
981 }
982 
getSymbolTableRegion(const DefinedAtom * atom,bool & inGlobalsRegion,SymbolScope & scope)983 llvm::Error Util::getSymbolTableRegion(const DefinedAtom* atom,
984                                        bool &inGlobalsRegion,
985                                        SymbolScope &scope) {
986   bool rMode = (_ctx.outputMachOType() == llvm::MachO::MH_OBJECT);
987   switch (atom->scope()) {
988   case Atom::scopeTranslationUnit:
989     scope = 0;
990     inGlobalsRegion = false;
991     return llvm::Error::success();
992   case Atom::scopeLinkageUnit:
993     if ((_ctx.exportMode() == MachOLinkingContext::ExportMode::exported) &&
994         _ctx.exportSymbolNamed(atom->name())) {
995       return llvm::make_error<GenericError>(
996                           Twine("cannot export hidden symbol ") + atom->name());
997     }
998     if (rMode) {
999       if (_ctx.keepPrivateExterns()) {
1000         // -keep_private_externs means keep in globals region as N_PEXT.
1001         scope = N_PEXT | N_EXT;
1002         inGlobalsRegion = true;
1003         return llvm::Error::success();
1004       }
1005     }
1006     // scopeLinkageUnit symbols are no longer global once linked.
1007     scope = N_PEXT;
1008     inGlobalsRegion = false;
1009     return llvm::Error::success();
1010   case Atom::scopeGlobal:
1011     if (_ctx.exportRestrictMode()) {
1012       if (_ctx.exportSymbolNamed(atom->name())) {
1013         scope = N_EXT;
1014         inGlobalsRegion = true;
1015         return llvm::Error::success();
1016       } else {
1017         scope = N_PEXT;
1018         inGlobalsRegion = false;
1019         return llvm::Error::success();
1020       }
1021     } else {
1022       scope = N_EXT;
1023       inGlobalsRegion = true;
1024       return llvm::Error::success();
1025     }
1026     break;
1027   }
1028   llvm_unreachable("atom->scope() unknown enum value");
1029 }
1030 
1031 
1032 
addSymbols(const lld::File & atomFile,NormalizedFile & file)1033 llvm::Error Util::addSymbols(const lld::File &atomFile,
1034                              NormalizedFile &file) {
1035   bool rMode = (_ctx.outputMachOType() == llvm::MachO::MH_OBJECT);
1036   // Mach-O symbol table has four regions: stabs, locals, globals, undefs.
1037 
1038   // Add all stabs.
1039   for (auto &stab : _stabs) {
1040     lld::mach_o::normalized::Symbol sym;
1041     sym.type = static_cast<NListType>(stab.type);
1042     sym.scope = 0;
1043     sym.sect = stab.other;
1044     sym.desc = stab.desc;
1045     if (stab.atom)
1046       sym.value = _atomToAddress[stab.atom];
1047     else
1048       sym.value = stab.value;
1049     sym.name = stab.str;
1050     file.stabsSymbols.push_back(sym);
1051   }
1052 
1053   // Add all local (non-global) symbols in address order
1054   std::vector<AtomAndIndex> globals;
1055   globals.reserve(512);
1056   for (SectionInfo *sect : _sectionInfos) {
1057     for (const AtomInfo &info : sect->atomsAndOffsets) {
1058       const DefinedAtom *atom = info.atom;
1059       if (!atom->name().empty()) {
1060         SymbolScope symbolScope;
1061         bool inGlobalsRegion;
1062         if (auto ec = getSymbolTableRegion(atom, inGlobalsRegion, symbolScope)){
1063           return ec;
1064         }
1065         if (inGlobalsRegion) {
1066           AtomAndIndex ai = { atom, sect->finalSectionIndex, symbolScope };
1067           globals.push_back(ai);
1068         } else {
1069           lld::mach_o::normalized::Symbol sym;
1070           sym.name  = atom->name();
1071           sym.type  = N_SECT;
1072           sym.scope = symbolScope;
1073           sym.sect  = sect->finalSectionIndex;
1074           sym.desc  = descBits(atom);
1075           sym.value = _atomToAddress[atom];
1076           _atomToSymbolIndex[atom] = file.localSymbols.size();
1077           file.localSymbols.push_back(sym);
1078         }
1079       } else if (rMode && _archHandler.needsLocalSymbolInRelocatableFile(atom)){
1080         // Create 'Lxxx' labels for anonymous atoms if archHandler says so.
1081         static unsigned tempNum = 1;
1082         char tmpName[16];
1083         sprintf(tmpName, "L%04u", tempNum++);
1084         StringRef tempRef(tmpName);
1085         lld::mach_o::normalized::Symbol sym;
1086         sym.name  = tempRef.copy(file.ownedAllocations);
1087         sym.type  = N_SECT;
1088         sym.scope = 0;
1089         sym.sect  = sect->finalSectionIndex;
1090         sym.desc  = 0;
1091         sym.value = _atomToAddress[atom];
1092         _atomToSymbolIndex[atom] = file.localSymbols.size();
1093         file.localSymbols.push_back(sym);
1094       }
1095     }
1096   }
1097 
1098   // Sort global symbol alphabetically, then add to symbol table.
1099   std::sort(globals.begin(), globals.end(), AtomSorter());
1100   const uint32_t globalStartIndex = file.localSymbols.size();
1101   for (AtomAndIndex &ai : globals) {
1102     lld::mach_o::normalized::Symbol sym;
1103     sym.name  = ai.atom->name();
1104     sym.type  = N_SECT;
1105     sym.scope = ai.scope;
1106     sym.sect  = ai.index;
1107     sym.desc  = descBits(static_cast<const DefinedAtom*>(ai.atom));
1108     sym.value = _atomToAddress[ai.atom];
1109     _atomToSymbolIndex[ai.atom] = globalStartIndex + file.globalSymbols.size();
1110     file.globalSymbols.push_back(sym);
1111   }
1112 
1113   // Sort undefined symbol alphabetically, then add to symbol table.
1114   std::vector<AtomAndIndex> undefs;
1115   undefs.reserve(128);
1116   for (const UndefinedAtom *atom : atomFile.undefined()) {
1117     AtomAndIndex ai = { atom, 0, N_EXT };
1118     undefs.push_back(ai);
1119   }
1120   for (const SharedLibraryAtom *atom : atomFile.sharedLibrary()) {
1121     AtomAndIndex ai = { atom, 0, N_EXT };
1122     undefs.push_back(ai);
1123   }
1124   std::sort(undefs.begin(), undefs.end(), AtomSorter());
1125   const uint32_t start = file.globalSymbols.size() + file.localSymbols.size();
1126   for (AtomAndIndex &ai : undefs) {
1127     lld::mach_o::normalized::Symbol sym;
1128     uint16_t desc = 0;
1129     if (!rMode) {
1130       uint8_t ordinal = 0;
1131       if (!_ctx.useFlatNamespace())
1132         ordinal = dylibOrdinal(dyn_cast<SharedLibraryAtom>(ai.atom));
1133       llvm::MachO::SET_LIBRARY_ORDINAL(desc, ordinal);
1134     }
1135     sym.name  = ai.atom->name();
1136     sym.type  = N_UNDF;
1137     sym.scope = ai.scope;
1138     sym.sect  = 0;
1139     sym.desc  = desc;
1140     sym.value = 0;
1141     _atomToSymbolIndex[ai.atom] = file.undefinedSymbols.size() + start;
1142     file.undefinedSymbols.push_back(sym);
1143   }
1144 
1145   return llvm::Error::success();
1146 }
1147 
targetOfLazyPointer(const DefinedAtom * lpAtom)1148 const Atom *Util::targetOfLazyPointer(const DefinedAtom *lpAtom) {
1149   for (const Reference *ref : *lpAtom) {
1150     if (_archHandler.isLazyPointer(*ref)) {
1151       return ref->target();
1152     }
1153   }
1154   return nullptr;
1155 }
1156 
targetOfStub(const DefinedAtom * stubAtom)1157 const Atom *Util::targetOfStub(const DefinedAtom *stubAtom) {
1158   for (const Reference *ref : *stubAtom) {
1159     if (const Atom *ta = ref->target()) {
1160       if (const DefinedAtom *lpAtom = dyn_cast<DefinedAtom>(ta)) {
1161         const Atom *target = targetOfLazyPointer(lpAtom);
1162         if (target)
1163           return target;
1164       }
1165     }
1166   }
1167   return nullptr;
1168 }
1169 
addIndirectSymbols(const lld::File & atomFile,NormalizedFile & file)1170 void Util::addIndirectSymbols(const lld::File &atomFile, NormalizedFile &file) {
1171   for (SectionInfo *si : _sectionInfos) {
1172     Section &normSect = file.sections[si->normalizedSectionIndex];
1173     switch (si->type) {
1174     case llvm::MachO::S_NON_LAZY_SYMBOL_POINTERS:
1175       for (const AtomInfo &info : si->atomsAndOffsets) {
1176         bool foundTarget = false;
1177         for (const Reference *ref : *info.atom) {
1178           const Atom *target = ref->target();
1179           if (target) {
1180             if (isa<const SharedLibraryAtom>(target)) {
1181               uint32_t index = _atomToSymbolIndex[target];
1182               normSect.indirectSymbols.push_back(index);
1183               foundTarget = true;
1184             } else {
1185               normSect.indirectSymbols.push_back(
1186                                             llvm::MachO::INDIRECT_SYMBOL_LOCAL);
1187             }
1188           }
1189         }
1190         if (!foundTarget) {
1191           normSect.indirectSymbols.push_back(
1192                                              llvm::MachO::INDIRECT_SYMBOL_ABS);
1193         }
1194       }
1195       break;
1196     case llvm::MachO::S_LAZY_SYMBOL_POINTERS:
1197       for (const AtomInfo &info : si->atomsAndOffsets) {
1198         const Atom *target = targetOfLazyPointer(info.atom);
1199         if (target) {
1200           uint32_t index = _atomToSymbolIndex[target];
1201           normSect.indirectSymbols.push_back(index);
1202         }
1203       }
1204       break;
1205     case llvm::MachO::S_SYMBOL_STUBS:
1206       for (const AtomInfo &info : si->atomsAndOffsets) {
1207         const Atom *target = targetOfStub(info.atom);
1208         if (target) {
1209           uint32_t index = _atomToSymbolIndex[target];
1210           normSect.indirectSymbols.push_back(index);
1211         }
1212       }
1213       break;
1214     default:
1215       break;
1216     }
1217   }
1218 }
1219 
addDependentDylibs(const lld::File & atomFile,NormalizedFile & nFile)1220 void Util::addDependentDylibs(const lld::File &atomFile,
1221                               NormalizedFile &nFile) {
1222   // Scan all imported symbols and build up list of dylibs they are from.
1223   int ordinal = 1;
1224   for (const auto *dylib : _ctx.allDylibs()) {
1225     DylibPathToInfo::iterator pos = _dylibInfo.find(dylib->installName());
1226     if (pos == _dylibInfo.end()) {
1227       DylibInfo info;
1228       bool flatNamespaceAtom = dylib == _ctx.flatNamespaceFile();
1229 
1230       // If we're in -flat_namespace mode (or this atom came from the flat
1231       // namespace file under -undefined dynamic_lookup) then use the flat
1232       // lookup ordinal.
1233       if (flatNamespaceAtom || _ctx.useFlatNamespace())
1234         info.ordinal = BIND_SPECIAL_DYLIB_FLAT_LOOKUP;
1235       else
1236         info.ordinal = ordinal++;
1237       info.hasWeak = false;
1238       info.hasNonWeak = !info.hasWeak;
1239       _dylibInfo[dylib->installName()] = info;
1240 
1241       // Unless this was a flat_namespace atom, record the source dylib.
1242       if (!flatNamespaceAtom) {
1243         DependentDylib depInfo;
1244         depInfo.path = dylib->installName();
1245         depInfo.kind = llvm::MachO::LC_LOAD_DYLIB;
1246         depInfo.currentVersion = _ctx.dylibCurrentVersion(dylib->path());
1247         depInfo.compatVersion = _ctx.dylibCompatVersion(dylib->path());
1248         nFile.dependentDylibs.push_back(depInfo);
1249       }
1250     } else {
1251       pos->second.hasWeak = false;
1252       pos->second.hasNonWeak = !pos->second.hasWeak;
1253     }
1254   }
1255   // Automatically weak link dylib in which all symbols are weak (canBeNull).
1256   for (DependentDylib &dep : nFile.dependentDylibs) {
1257     DylibInfo &info = _dylibInfo[dep.path];
1258     if (info.hasWeak && !info.hasNonWeak)
1259       dep.kind = llvm::MachO::LC_LOAD_WEAK_DYLIB;
1260     else if (_ctx.isUpwardDylib(dep.path))
1261       dep.kind = llvm::MachO::LC_LOAD_UPWARD_DYLIB;
1262   }
1263 }
1264 
dylibOrdinal(const SharedLibraryAtom * sa)1265 int Util::dylibOrdinal(const SharedLibraryAtom *sa) {
1266   return _dylibInfo[sa->loadName()].ordinal;
1267 }
1268 
segIndexForSection(const SectionInfo * sect,uint8_t & segmentIndex,uint64_t & segmentStartAddr)1269 void Util::segIndexForSection(const SectionInfo *sect, uint8_t &segmentIndex,
1270                                                   uint64_t &segmentStartAddr) {
1271   segmentIndex = 0;
1272   for (const SegmentInfo *seg : _segmentInfos) {
1273     if ((seg->address <= sect->address)
1274       && (seg->address+seg->size >= sect->address+sect->size)) {
1275       segmentStartAddr = seg->address;
1276       return;
1277     }
1278     ++segmentIndex;
1279   }
1280   llvm_unreachable("section not in any segment");
1281 }
1282 
sectionIndexForAtom(const Atom * atom)1283 uint32_t Util::sectionIndexForAtom(const Atom *atom) {
1284   uint64_t address = _atomToAddress[atom];
1285   for (const SectionInfo *si : _sectionInfos) {
1286     if ((si->address <= address) && (address < si->address+si->size))
1287       return si->finalSectionIndex;
1288   }
1289   llvm_unreachable("atom not in any section");
1290 }
1291 
addSectionRelocs(const lld::File &,NormalizedFile & file)1292 void Util::addSectionRelocs(const lld::File &, NormalizedFile &file) {
1293   if (_ctx.outputMachOType() != llvm::MachO::MH_OBJECT)
1294     return;
1295 
1296   // Utility function for ArchHandler to find symbol index for an atom.
1297   auto symIndexForAtom = [&] (const Atom &atom) -> uint32_t {
1298     auto pos = _atomToSymbolIndex.find(&atom);
1299     assert(pos != _atomToSymbolIndex.end());
1300     return pos->second;
1301   };
1302 
1303   // Utility function for ArchHandler to find section index for an atom.
1304   auto sectIndexForAtom = [&] (const Atom &atom) -> uint32_t {
1305     return sectionIndexForAtom(&atom);
1306   };
1307 
1308   // Utility function for ArchHandler to find address of atom in output file.
1309   auto addressForAtom = [&] (const Atom &atom) -> uint64_t {
1310     auto pos = _atomToAddress.find(&atom);
1311     assert(pos != _atomToAddress.end());
1312     return pos->second;
1313   };
1314 
1315   for (SectionInfo *si : _sectionInfos) {
1316     Section &normSect = file.sections[si->normalizedSectionIndex];
1317     for (const AtomInfo &info : si->atomsAndOffsets) {
1318       const DefinedAtom *atom = info.atom;
1319       for (const Reference *ref : *atom) {
1320         // Skip emitting relocs for sections which are always able to be
1321         // implicitly regenerated and where the relocation targets an address
1322         // which is defined.
1323         if (si->relocsToDefinedCanBeImplicit && isa<DefinedAtom>(ref->target()))
1324           continue;
1325         _archHandler.appendSectionRelocations(*atom, info.offsetInSection, *ref,
1326                                               symIndexForAtom,
1327                                               sectIndexForAtom,
1328                                               addressForAtom,
1329                                               normSect.relocations);
1330       }
1331     }
1332   }
1333 }
1334 
addFunctionStarts(const lld::File &,NormalizedFile & file)1335 void Util::addFunctionStarts(const lld::File &, NormalizedFile &file) {
1336   if (!_ctx.generateFunctionStartsLoadCommand())
1337     return;
1338   file.functionStarts.reserve(8192);
1339   // Delta compress function starts, starting with the mach header symbol.
1340   const uint64_t badAddress = ~0ULL;
1341   uint64_t addr = badAddress;
1342   for (SectionInfo *si : _sectionInfos) {
1343     for (const AtomInfo &info : si->atomsAndOffsets) {
1344       auto type = info.atom->contentType();
1345       if (type == DefinedAtom::typeMachHeader) {
1346         addr = _atomToAddress[info.atom];
1347         continue;
1348       }
1349       if (type != DefinedAtom::typeCode)
1350         continue;
1351       assert(addr != badAddress && "Missing mach header symbol");
1352       // Skip atoms which have 0 size.  This is so that LC_FUNCTION_STARTS
1353       // can't spill in to the next section.
1354       if (!info.atom->size())
1355         continue;
1356       uint64_t nextAddr = _atomToAddress[info.atom];
1357       if (_archHandler.isThumbFunction(*info.atom))
1358         nextAddr |= 1;
1359       uint64_t delta = nextAddr - addr;
1360       if (delta) {
1361         ByteBuffer buffer;
1362         buffer.append_uleb128(delta);
1363         file.functionStarts.insert(file.functionStarts.end(), buffer.bytes(),
1364                                    buffer.bytes() + buffer.size());
1365       }
1366       addr = nextAddr;
1367     }
1368   }
1369 
1370   // Null terminate, and pad to pointer size for this arch.
1371   file.functionStarts.push_back(0);
1372 
1373   auto size = file.functionStarts.size();
1374   for (unsigned i = size, e = llvm::alignTo(size, _ctx.is64Bit() ? 8 : 4);
1375        i != e; ++i)
1376     file.functionStarts.push_back(0);
1377 }
1378 
buildDataInCodeArray(const lld::File &,NormalizedFile & file)1379 void Util::buildDataInCodeArray(const lld::File &, NormalizedFile &file) {
1380   if (!_ctx.generateDataInCodeLoadCommand())
1381     return;
1382   for (SectionInfo *si : _sectionInfos) {
1383     for (const AtomInfo &info : si->atomsAndOffsets) {
1384       // Atoms that contain data-in-code have "transition" references
1385       // which mark a point where the embedded data starts of ends.
1386       // This needs to be converted to the mach-o format which is an array
1387       // of data-in-code ranges.
1388       uint32_t startOffset = 0;
1389       DataRegionType mode = DataRegionType(0);
1390       for (const Reference *ref : *info.atom) {
1391         if (ref->kindNamespace() != Reference::KindNamespace::mach_o)
1392           continue;
1393         if (_archHandler.isDataInCodeTransition(ref->kindValue())) {
1394           DataRegionType nextMode = (DataRegionType)ref->addend();
1395           if (mode != nextMode) {
1396             if (mode != 0) {
1397               // Found end data range, so make range entry.
1398               DataInCode entry;
1399               entry.offset = si->address + info.offsetInSection + startOffset;
1400               entry.length = ref->offsetInAtom() - startOffset;
1401               entry.kind   = mode;
1402               file.dataInCode.push_back(entry);
1403             }
1404           }
1405           mode = nextMode;
1406           startOffset = ref->offsetInAtom();
1407         }
1408       }
1409       if (mode != 0) {
1410         // Function ends with data (no end transition).
1411         DataInCode entry;
1412         entry.offset = si->address + info.offsetInSection + startOffset;
1413         entry.length = info.atom->size() - startOffset;
1414         entry.kind   = mode;
1415         file.dataInCode.push_back(entry);
1416       }
1417     }
1418   }
1419 }
1420 
addRebaseAndBindingInfo(const lld::File & atomFile,NormalizedFile & nFile)1421 void Util::addRebaseAndBindingInfo(const lld::File &atomFile,
1422                                                         NormalizedFile &nFile) {
1423   if (_ctx.outputMachOType() == llvm::MachO::MH_OBJECT)
1424     return;
1425 
1426   uint8_t segmentIndex;
1427   uint64_t segmentStartAddr;
1428   uint32_t offsetInBindInfo = 0;
1429 
1430   for (SectionInfo *sect : _sectionInfos) {
1431     segIndexForSection(sect, segmentIndex, segmentStartAddr);
1432     for (const AtomInfo &info : sect->atomsAndOffsets) {
1433       const DefinedAtom *atom = info.atom;
1434       for (const Reference *ref : *atom) {
1435         uint64_t segmentOffset = _atomToAddress[atom] + ref->offsetInAtom()
1436                                 - segmentStartAddr;
1437         const Atom* targ = ref->target();
1438         if (_archHandler.isPointer(*ref)) {
1439           // A pointer to a DefinedAtom requires rebasing.
1440           if (isa<DefinedAtom>(targ)) {
1441             RebaseLocation rebase;
1442             rebase.segIndex = segmentIndex;
1443             rebase.segOffset = segmentOffset;
1444             rebase.kind = llvm::MachO::REBASE_TYPE_POINTER;
1445             nFile.rebasingInfo.push_back(rebase);
1446           }
1447           // A pointer to an SharedLibraryAtom requires binding.
1448           if (const SharedLibraryAtom *sa = dyn_cast<SharedLibraryAtom>(targ)) {
1449             BindLocation bind;
1450             bind.segIndex = segmentIndex;
1451             bind.segOffset = segmentOffset;
1452             bind.kind = llvm::MachO::BIND_TYPE_POINTER;
1453             bind.canBeNull = sa->canBeNullAtRuntime();
1454             bind.ordinal = dylibOrdinal(sa);
1455             bind.symbolName = targ->name();
1456             bind.addend = ref->addend();
1457             nFile.bindingInfo.push_back(bind);
1458           }
1459         }
1460         else if (_archHandler.isLazyPointer(*ref)) {
1461           BindLocation bind;
1462           if (const SharedLibraryAtom *sa = dyn_cast<SharedLibraryAtom>(targ)) {
1463             bind.ordinal = dylibOrdinal(sa);
1464           } else {
1465             bind.ordinal = llvm::MachO::BIND_SPECIAL_DYLIB_SELF;
1466           }
1467           bind.segIndex = segmentIndex;
1468           bind.segOffset = segmentOffset;
1469           bind.kind = llvm::MachO::BIND_TYPE_POINTER;
1470           bind.canBeNull = false; //sa->canBeNullAtRuntime();
1471           bind.symbolName = targ->name();
1472           bind.addend = ref->addend();
1473           nFile.lazyBindingInfo.push_back(bind);
1474 
1475           // Now that we know the segmentOffset and the ordinal attribute,
1476           // we can fix the helper's code
1477 
1478           fixLazyReferenceImm(atom, offsetInBindInfo, nFile);
1479 
1480           // 5 bytes for opcodes + variable sizes (target name + \0 and offset
1481           // encode's size)
1482           offsetInBindInfo +=
1483               6 + targ->name().size() + llvm::getULEB128Size(bind.segOffset);
1484           if (bind.ordinal > BIND_IMMEDIATE_MASK)
1485             offsetInBindInfo += llvm::getULEB128Size(bind.ordinal);
1486         }
1487       }
1488     }
1489   }
1490 }
1491 
fixLazyReferenceImm(const DefinedAtom * atom,uint32_t offset,NormalizedFile & file)1492 void Util::fixLazyReferenceImm(const DefinedAtom *atom, uint32_t offset,
1493                                NormalizedFile &file) {
1494   for (const Reference *ref : *atom) {
1495     const DefinedAtom *da = dyn_cast<DefinedAtom>(ref->target());
1496     if (da == nullptr)
1497       return;
1498 
1499     const Reference *helperRef = nullptr;
1500     for (const Reference *hr : *da) {
1501       if (hr->kindValue() == _archHandler.lazyImmediateLocationKind()) {
1502         helperRef = hr;
1503         break;
1504       }
1505     }
1506     if (helperRef == nullptr)
1507       continue;
1508 
1509     // TODO: maybe get the fixed atom content from _archHandler ?
1510     for (SectionInfo *sectInfo : _sectionInfos) {
1511       for (const AtomInfo &atomInfo : sectInfo->atomsAndOffsets) {
1512         if (atomInfo.atom == helperRef->target()) {
1513           auto sectionContent =
1514               file.sections[sectInfo->normalizedSectionIndex].content;
1515           uint8_t *rawb =
1516               file.ownedAllocations.Allocate<uint8_t>(sectionContent.size());
1517           llvm::MutableArrayRef<uint8_t> newContent{rawb,
1518                                                     sectionContent.size()};
1519           std::copy(sectionContent.begin(), sectionContent.end(),
1520                     newContent.begin());
1521           llvm::support::ulittle32_t *loc =
1522               reinterpret_cast<llvm::support::ulittle32_t *>(
1523                   &newContent[atomInfo.offsetInSection +
1524                               helperRef->offsetInAtom()]);
1525           *loc = offset;
1526           file.sections[sectInfo->normalizedSectionIndex].content = newContent;
1527         }
1528       }
1529     }
1530   }
1531 }
1532 
addExportInfo(const lld::File & atomFile,NormalizedFile & nFile)1533 void Util::addExportInfo(const lld::File &atomFile, NormalizedFile &nFile) {
1534   if (_ctx.outputMachOType() == llvm::MachO::MH_OBJECT)
1535     return;
1536 
1537   for (SectionInfo *sect : _sectionInfos) {
1538     for (const AtomInfo &info : sect->atomsAndOffsets) {
1539       const DefinedAtom *atom = info.atom;
1540       if (atom->scope() != Atom::scopeGlobal)
1541         continue;
1542       if (_ctx.exportRestrictMode()) {
1543         if (!_ctx.exportSymbolNamed(atom->name()))
1544           continue;
1545       }
1546       Export exprt;
1547       exprt.name = atom->name();
1548       exprt.offset = _atomToAddress[atom] - _ctx.baseAddress();
1549       exprt.kind = EXPORT_SYMBOL_FLAGS_KIND_REGULAR;
1550       if (atom->merge() == DefinedAtom::mergeAsWeak)
1551         exprt.flags = EXPORT_SYMBOL_FLAGS_WEAK_DEFINITION;
1552       else
1553         exprt.flags = 0;
1554       exprt.otherOffset = 0;
1555       exprt.otherName = StringRef();
1556       nFile.exportInfo.push_back(exprt);
1557     }
1558   }
1559 }
1560 
fileFlags()1561 uint32_t Util::fileFlags() {
1562   // FIXME: these need to determined at runtime.
1563   if (_ctx.outputMachOType() == MH_OBJECT) {
1564     return _subsectionsViaSymbols ? MH_SUBSECTIONS_VIA_SYMBOLS : 0;
1565   } else {
1566     uint32_t flags = MH_DYLDLINK;
1567     if (!_ctx.useFlatNamespace())
1568         flags |= MH_TWOLEVEL | MH_NOUNDEFS;
1569     if ((_ctx.outputMachOType() == MH_EXECUTE) && _ctx.PIE())
1570       flags |= MH_PIE;
1571     if (_hasTLVDescriptors)
1572       flags |= (MH_PIE | MH_HAS_TLV_DESCRIPTORS);
1573     return flags;
1574   }
1575 }
1576 
1577 } // end anonymous namespace
1578 
1579 namespace lld {
1580 namespace mach_o {
1581 namespace normalized {
1582 
1583 /// Convert a set of Atoms into a normalized mach-o file.
1584 llvm::Expected<std::unique_ptr<NormalizedFile>>
normalizedFromAtoms(const lld::File & atomFile,const MachOLinkingContext & context)1585 normalizedFromAtoms(const lld::File &atomFile,
1586                                            const MachOLinkingContext &context) {
1587   // The util object buffers info until the normalized file can be made.
1588   Util util(context);
1589   util.processDefinedAtoms(atomFile);
1590   util.organizeSections();
1591 
1592   std::unique_ptr<NormalizedFile> f(new NormalizedFile());
1593   NormalizedFile &normFile = *f.get();
1594   normFile.arch = context.arch();
1595   normFile.fileType = context.outputMachOType();
1596   normFile.flags = util.fileFlags();
1597   normFile.stackSize = context.stackSize();
1598   normFile.installName = context.installName();
1599   normFile.currentVersion = context.currentVersion();
1600   normFile.compatVersion = context.compatibilityVersion();
1601   normFile.os = context.os();
1602 
1603   // If we are emitting an object file, then the min version is the maximum
1604   // of the min's of all the source files and the cmdline.
1605   if (normFile.fileType == llvm::MachO::MH_OBJECT)
1606     normFile.minOSverson = std::max(context.osMinVersion(), util.minVersion());
1607   else
1608     normFile.minOSverson = context.osMinVersion();
1609 
1610   normFile.minOSVersionKind = util.minVersionCommandType();
1611 
1612   normFile.sdkVersion = context.sdkVersion();
1613   normFile.sourceVersion = context.sourceVersion();
1614 
1615   if (context.generateVersionLoadCommand() &&
1616       context.os() != MachOLinkingContext::OS::unknown)
1617     normFile.hasMinVersionLoadCommand = true;
1618   else if (normFile.fileType == llvm::MachO::MH_OBJECT &&
1619            util.allSourceFilesHaveMinVersions() &&
1620            ((normFile.os != MachOLinkingContext::OS::unknown) ||
1621             util.minVersionCommandType())) {
1622     // If we emit an object file, then it should contain a min version load
1623     // command if all of the source files also contained min version commands.
1624     // Also, we either need to have a platform, or found a platform from the
1625     // source object files.
1626     normFile.hasMinVersionLoadCommand = true;
1627   }
1628   normFile.generateDataInCodeLoadCommand =
1629     context.generateDataInCodeLoadCommand();
1630   normFile.pageSize = context.pageSize();
1631   normFile.rpaths = context.rpaths();
1632   util.addDependentDylibs(atomFile, normFile);
1633   util.copySegmentInfo(normFile);
1634   util.copySectionInfo(normFile);
1635   util.assignAddressesToSections(normFile);
1636   util.buildAtomToAddressMap();
1637   if (auto err = util.synthesizeDebugNotes(normFile))
1638     return std::move(err);
1639   util.updateSectionInfo(normFile);
1640   util.copySectionContent(normFile);
1641   if (auto ec = util.addSymbols(atomFile, normFile)) {
1642     return std::move(ec);
1643   }
1644   util.addIndirectSymbols(atomFile, normFile);
1645   util.addRebaseAndBindingInfo(atomFile, normFile);
1646   util.addExportInfo(atomFile, normFile);
1647   util.addSectionRelocs(atomFile, normFile);
1648   util.addFunctionStarts(atomFile, normFile);
1649   util.buildDataInCodeArray(atomFile, normFile);
1650   util.copyEntryPointAddress(normFile);
1651 
1652   return std::move(f);
1653 }
1654 
1655 } // namespace normalized
1656 } // namespace mach_o
1657 } // namespace lld
1658